There is provided an information processing device and method capable of performing remote control with higher accuracy. With respect to a plurality of observation points of a device serving as an interface, haptic data including at least one piece of kinesthetic data including information on a kinesthetic sensation detected at the observation points, tactile data including information on a tactile sensation detected at the observation points, and force data including information on a magnitude of force applied to the observation points is transmitted. The present disclosure can be applied to, for example, an information processing device, a control device, an electronic apparatus, an information processing method, a program, or the like.

Apparatus and methods are described including a robotic unit configured to move the tool through six degrees-of-freedom, and a control component that comprises at least one control-component arm configured to be moved by a user, The control-component arm includes three rotary encoders, each of the three rotary encoders coupled to a respective joint and configured to detect movement of the respective joint and to generate rotary-encoder data indicative of an XYZ location of a tip of the control-component tool, in response thereto, and an inertial measurement unit comprising at least one of a three-axis accelerometer, a three-axis gyroscope, and a three-axis magnetometer, the inertial measurement unit being configured to generate inertial-measurement-unit data indicative of an orientation of the tip of control-component tool. Other applications are also described.

Apparatus and methods are described including a robotic unit configured to move the tool through six degrees-of-freedom, and a control component that comprises at least one control-component arm configured to be moved by a user, The control-component arm includes three rotary encoders, each of the three rotary encoders coupled to a respective joint and configured to detect movement of the respective joint and to generate rotary-encoder data indicative of an XYZ location of a tip of the control-component tool, in response thereto, and an inertial measurement unit comprising at least one of a three-axis accelerometer, a three-axis gyroscope, and a three-axis magnetometer, the inertial measurement unit being configured to generate inertial-measurement-unit data indicative of an orientation of the tip of control-component tool. Other applications are also described.

A console for controlling a robotic manipulator having an end effector, the console comprising: a hand controller connected to a gimbal assembly; and an articulated linkage connected at its proximal end to a rigid support structure, and at its distal end to the gimbal assembly. The gimbal assembly comprises only three degrees of freedom provided by only three joints, a first joint of the three joints permitting the gimbal assembly to rotate relative to the distal end of the articulated linkage about a first axis. The articulated linkage and gimbal assembly are arranged such that in every configuration of the articulated linkage and gimbal assembly, the first axis has the same orientation relative to the support structure. The articulated linkage has a parallelogram profile thereby mechanically constraining the first axis to have the same orientation relative to the support structure in every configuration of the articulated linkage.

A universal actuator for driving a continuum arm robot having a plurality of tendons includes; a housing; a power supply pack with a power source; a control pack with an industrial programmable logic controller, a screen, a rotary encoder linked to an analogue input device, a digital output device, a plurality of electronic control cards that connect the programmable logic controller to a user input device, the rotary encoder and an actuator pack for controlling the motion of the continuum arm robot, the programmable logic controller or the screen having a computer program to allow for set up and control of the continuum arm robot.

A universal actuator for driving a continuum arm robot having a plurality of tendons includes; a housing; a power supply pack with a power source; a control pack with an industrial programmable logic controller, a screen, a rotary encoder linked to an analogue input device, a digital output device, a plurality of electronic control cards that connect the programmable logic controller to a user input device, the rotary encoder and an actuator pack for controlling the motion of the continuum arm robot, the programmable logic controller or the screen having a computer program to allow for set up and control of the continuum arm robot.

Devices, Systems, and Methods for controlled movement of the robot system. The surgical robot system may include a robot having a robot base, a robot arm coupled to the robot base, and an end-effector coupled to the robot arm. The robot may include a plurality of omni-directional wheels affixed to the robot base allowing multiple-axis movement of the robot. The robot may further include sensors for detecting a desired movement of the robot base and a control system responsive to the plurality of sensors for controlling the multiple-axis movement of the robot by actuating two or more of the plurality of omni-directional wheels.

A control device for robot arm is provided that comprises: an elastic member comprising a palm portion and a finger portion, the palm portion being coupled to the finger portion, the elastic member being adapted to receive a part of body of a user; a detecting electrode located on an inner surface of the palm portion and configured to detect a surface electromyogram signal of the part of body for identifying a gesture of the part of body of the user; a sensor located on the elastic member for acquiring data relating to a three-dimensional motion of the part of body of the user to identify the three-dimensional motion of the part of body of the user, wherein the surface electromyogram signal and the data relating the three-dimensional motion are adaptable to be used to control the robot arm to perform the gesture and the three-dimensional motion.

Wearable user interface devices are described. A wearable user interface device can include a wearable base connected to a trackable device component by a linkage. The linkage can connect to a pivoted support that the trackable device is mounted on, and which maintains poses when the user interface device is not manipulated by a user's hand. The pivoted support has several orthogonal axes intersecting at a center of rotation located inside a device body of the trackable device. Other embodiments are also described and claimed.

Wearable user interface devices are described. A wearable user interface device can include a wearable base connected to a trackable device component by a linkage. The linkage can connect to a pivoted support that the trackable device is mounted on, and which maintains poses when the user interface device is not manipulated by a user's hand. The pivoted support has several orthogonal axes intersecting at a center of rotation located inside a device body of the trackable device. Other embodiments are also described and claimed.